Universal quantum encryption for quantum signature using the swap test

We suggest a universal quantum encryption scheme suitable for use in quantum signature. The verifier in a variety of quantum signature protocols usually checks for the falsification of the quantum signature state pair by using a swap test. However, these quantum signature protocols are not secure ag...

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Veröffentlicht in:	Quantum information processing 2018-10, Vol.17 (10), p.1-11, Article 254
Hauptverfasser:	Kang, Min-Sung, Choi, Ho-Won, Pramanik, Tanumoy, Han, Sang-Wook, Moon, Sung
Format:	Artikel
Sprache:	eng
Schlagworte:	Commutativity Data Structures and Information Theory Encryption Forgery Mathematical Physics Physics Physics and Astronomy Quantum Computing Quantum encryption Quantum Information Technology Quantum Physics Spintronics
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container_title	Quantum information processing
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creator	Kang, Min-Sung Choi, Ho-Won Pramanik, Tanumoy Han, Sang-Wook Moon, Sung
description	We suggest a universal quantum encryption scheme suitable for use in quantum signature. The verifier in a variety of quantum signature protocols usually checks for the falsification of the quantum signature state pair by using a swap test. However, these quantum signature protocols are not secure against existential forgery attacks; We prove that the universal quantum encryption scheme proposed in this paper is secure against this type of forgery because it uses the non-(anti)commutativity of an arbitrary unitary operator. In addition, we demonstrate its use in a quantum signature. Moreover, the optimization of this encryption in comparison with other encryption schemes is presented.
doi_str_mv	10.1007/s11128-018-2029-0
format	Article
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subjects	Commutativity Data Structures and Information Theory Encryption Forgery Mathematical Physics Physics Physics and Astronomy Quantum Computing Quantum encryption Quantum Information Technology Quantum Physics Spintronics
title	Universal quantum encryption for quantum signature using the swap test
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